A manually-operated coded image animation device a coded image viewer with a front panel, a reception area, such as a slot open on three sides or a channel, behind the front panel, and coded image decoding elements disposed on the front panel. A coded image card with a plurality of coded images can be manually inserted into the reception area in the coded image viewer. Animation of the coded images can be realized by a sliding movement of the coded image card in relation to the coded image viewer or by a rearward and forward rocking of the coded image viewer in relation to a podium by manual activation. A pivoting structure can be formed by a lever arm, a counterweight, and the coded image viewer with the lever arm received through a slot in the podium. A biasing system biases the coded image card into face-to-face contact with the front panel.

A manually-operated coded image animation device a coded image viewer with a front panel, a reception area, such as a slot open on three sides or a channel, behind the front panel, and coded image decoding elements disposed on the front panel. A coded image card with a plurality of coded images can be manually inserted into the reception area in the coded image viewer. Animation of the coded images can be realized by a sliding movement of the coded image card in relation to the coded image viewer or by a rearward and forward rocking of the coded image viewer in relation to a podium by manual activation. A pivoting structure can be formed by a lever arm, a counterweight, and the coded image viewer with the lever arm received through a slot in the podium. A biasing system biases the coded image card into face-to-face contact with the front panel.

A lenticular display includes a lenticular image including an image strip group in which display image strips that are respectively extracted in the form of a stripe from a plurality of display images are arrayed adjacently to each other in their respective corresponding positions, and in which an interpolation image strip is disposed between display image strips that are adjacent to each other, that are extracted from different display images, and that have different colors in at least a portion thereof, the interpolation image strip having a color that is in between the color of one of the adjacent display image strips and the color of the other of the adjacent display image strips.

To make a displayed image clear. A display device emits image light reflected by a plurality of prisms (141) provided in a light guide plate (14) from a light exit surface (14c). The prism (141) has a reflective surface (141a) that reflects and emits the image light. The reflective surface (141a) is formed in a curved shape in a thickness direction of the light guide plate (14).

A general purpose image and visual effects display apparatus, with associated methods, which is comprised of an array of independently angled reflective or refractive elements wherein the varying angle pattern of each element across said array is designed to reflect or refract specifically designed as well as fortuitously located existing colors, in precisely determined patterns, to make apparent to specific viewing or receiving locations a wide range of complex emergent visual and other effects. In some embodiments very high resolution and high color fidelity image display is possible. In other embodiments moving images akin to video can be displayed, using no electronics or moving parts. In other embodiments true binocular 3D images can be displayed directly to viewers, without the need for special 3D viewing glasses. Many of the embodiments and methods are applicable to non-visible light and other reflectable wave-based phenomena.

A general purpose image and visual effects display apparatus, with associated methods, which is comprised of an array of independently angled reflective or refractive elements wherein the varying angle pattern of each element across said array is designed to reflect or refract specifically designed as well as fortuitously located existing colors, in precisely determined patterns, to make apparent to specific viewing or receiving locations a wide range of complex emergent visual and other effects. In some embodiments very high resolution and high color fidelity image display is possible. In other embodiments moving images akin to video can be displayed, using no electronics or moving parts. In other embodiments true binocular 3D images can be displayed directly to viewers, without the need for special 3D viewing glasses. Many of the embodiments and methods are applicable to non-visible light and other reflectable wave-based phenomena.

A rotatable stroboscopic animation device with a rotatable base portion and at least one light source. An angular-velocity-dependent flashing system flashes the at least one light source according to a predetermined flash mode dependent on the angular velocity of the base portion to produce coherent, automatic stroboscopic animation of images retained by the base portion. The flashing system can comprise an angular velocity determination system in cooperation with an illumination system. Angular velocity can be determined by an orienting system, such as a compass, in combination with a sampling system, a gyroscope, or a rotational sensor. A flash mode selection mechanism, which can be manual or automatic, permits a selection of a flash mode from among a plurality of flash modes. A manual flash mode selection mechanism can be formed by relatively pivotable upper and lower disks of the base portion. Animation disks can have indications of predetermined flash modes.

A lenticular display has: a lenticular lens in which a plurality of convex lenses are arranged in parallel, each of the convex lenses having a convex front surface; a lenticular image provided on a back surface side of each of the convex lenses; and an anti-reflection layer provided on a back surface side of the lenticular image. The lenticular image includes a plurality of display image strips that are extracted each in a stripe shape from a plurality of display images and that are arranged at corresponding positions on the back surface side of each of the convex lenses, and a transparent-slit image strip that is provided between each pair of the plurality of display image strips that are adjacent to each other and that are extracted from the display images that differ from each other.

A lenticular display has: a lenticular lens in which a plurality of convex lenses are arranged side by side, the plurality of convex lenses each having a convex surface; and a lenticular image provided on a back-face side facing away from the surface of the convex lenses. Provided are the lenticular display in which the lenticular image is a plurality of display image strips that are extracted from each of a plurality of display images in a stripe form and are arranged at corresponding positions under the convex lenses, and in the plurality of display images, a color density of a portion where main-image parts overlap with each other is corrected, a method for forming a lenticular image, a method for manufacturing the lenticular display, and a program for forming a lenticular image.

A method for producing a security element formed as a lenticular flip, including a micro-optical layer, a carrier substrate and an image layer, wherein the image layer includes n images for n=1 to i which are visible from an n-th observation angle allocated to the n-th image, and wherein n is at least 1. The images are imaged on a photoresist with parallel light in contact print or by means of projection. After the photoresist is developed, an image layer which includes the i images is present.